TW200814312A - Semiconductor device with reliable high-voltage gate oxide and method of manufacture thereof - Google Patents

Abstract

A semiconductor device including a capacitor and a proximate high-voltage gate having a boron-barrier layer that ideally serves as part of both the capacitor dielectric and the (high voltage) HV gate oxide. The boron-barrier layer is preferably formed over a poly oxide layer that is in turn deposited on a substrate infused to create a neighboring wells, and N-well over which the capacitor will be formed, and P-well to be overlaid by the HV gate. The boron-barrier helps to reduced or eliminate the harmful effects of boron diffusion from the P-well during TEOS deposition of the gate oxide material.

Description

200814312 IX. Description of the invention: [Technical field to which the invention pertains] Right milk 2 is related to a semiconductor element and a method of forming the same, and in particular, when a piece is grown, due to diffusion of boron to a high-voltage gate electrode emulsifying layer Unstable. [Electricity] ::: The components have been used in a large number of applications, and the power is two;:: or missing. Applications include computers, music, and more. The reason why electronic components are widely used is that μH and cost are reduced. Therefore, the technical improvement has become an important part of the conductor components of the exhibition.巳The following is a brief description of the material used to form the semi-material, such as Shi Xi, as the process of the „ piece. The electric 卞兀 piece. This material is formed into a sheet of ten rounds. Then selectively categorized: nickname The semiconductor characteristics of the crystal. Finally, the various two == can obtain the required components. (3) formed on the day a to obtain the surface structure on the wafer can be exposed to an etchant. Finished. Wafer-based technology for selective guided lithography; Li: Xi: lithography material is deposited evenly on the surface of the wafer. This resistance or other resist-mask will be part of the resistance (4) Exposure and passing through °503-A32446TWF/kai 200814312 The exposed photoresist will become harder or more fragile, and then the solvent can be used to remove the weaker part, and the remaining photoresist can protect the surface of the wafer from being etched. Erosion. When the wafer etch process is completed, the previously remaining photoresist is removed by a suitable solvent. In addition, various deposition techniques can be used to deposit other materials, such as metals or other conductive and insulating materials, on the wafer surface. , for example, to Deposited by vapor deposition (CVD) or sputtering. Additional ions can be implanted. Then, various materials are selectively deposited and removed to form a layered electronic component structure on the surface of the wafer. The circle usually contains a plurality of grains. Usually, the grains are all of the same structure, but not absolute. After all processes are completed (or in the middle of the process), the wafer can be inspected and tested, and the damaged portion is moved. In addition, or after repair, the separated and tested die is packaged in a hard plastic material and connected to the inside of the die by external wires. The packaged die has many wires, which can also be called wafers. Components can be formed on the wafer at the same time. When a material is deposited or selectively burned, the material can be used for many of the same or different components. Therefore, careful design is required to make it economical, for example, at high voltage. In the application of high voltage mixed mode (HV-M.Μ), the semiconductor device has a capacitor structure and is placed in an NMOS low voltage (LV) gate and an NMOS high voltage (H). V) Between the gates, as shown in Figures 1A-1F. Figures 1A-1F are conventional process profiles of the semiconductor component 10. It should be noted that the "half 0503-A32446TWF/kai 6 200814312" described herein may A wafer formed of one or more dies, and in the 'below' is an element or process that describes a particular portion of the die. The preparation of the board semiconductor component 10 is first formed into a substrate 2 () and a material 2 (). In this step

Figure,. The second is used to support three components (please refer to the 1F ..., the semiconductor component of the g! diagram includes the germanium-related structure. Then the field oxide structure 30, 31, 3-2 is formed: the same as the ^) HV idler The oxide layer 35 is formed on the p-type well 15, which is not the second iTEOS (five). The HV inter-electrode oxide layer 35 can be produced by using tetraethoxy stellite w ΓΓΥ1 orth〇siiicat^^. In the material, the pattern produced by the order is also called "patterning," π and the second _ oxide layer 4G is formed in the semiconductor as shown in Figure 1C. Then a surface is formed, which is electrically conductive. The layer is formed to form a conductive:: 晶晶石 夕), and select 闰--, 丄# electric,,, mouth structure 45, 46 and 47, such as the lower conductive layer of the m-th second-capacitor, the conductive structure 45 is a HV gate Pole, conductive structure 4 苒5

The figure shows. Finally, the surface of the second lead Ley 1E high temperature oxide layer 5G is formed by the surface of the polycrystalline intergranular oxide layer/piece 1〇 as shown in the second figure: side =, formed by the above conventional process Hv closed-end oxidation of reed and 1 is not good and so on. The low stability of the inter-electrode oxide layer is 〇503-A32446TWF/kai /曙 14312 in the TEQU material. Therefore, the semiconductor industry, the method of dispersion caused by the dispersion. BACKGROUND OF THE INVENTION The present invention provides a high stability to deposition of an ion-blocking V-body prior to formation into a free-standing oxide layer, which is based on the stability of the shaped oxide layer. (3) From the addition of HV gates, the system provides a semiconductor pattern to be appropriate: structure 2: === growth of multiple layers of layers, 纟,, dielectric layer ΐ: more than two ^ nitrogen layer can be - film. On -ί: on the substrate (or - the diffusion of ions caused by the decomposition of the polycrystalline 7-ion etched early layered polar oxide layer. f In another embodiment, the ion barrier layer includes = zinc (ZnO ^ ^ ( TaX〇yNz), Nitrogen Oxidation (cooking), Nitrogen Oxide, X=Listening and Nitrogen-cutting, medium x is a positive integer, and y and z are any non-negative integers. The capacitor dielectric layer and the ion barrier layer are deposited in the same order. The present invention also provides a method for forming a semiconductor component, including a 〇503-A32446TWF/kai 200814312 for inclusion of a single-day 9-day yen, and on the substrate (4) Forming a plurality of wells, one in-well': well and and :: 7r: forming one (10) In this embodiment, the second brother:: the electrical structure is on the oxide layer and the n-type well. Upper, and - long / μ The layer is then formed on the entire component and a layer of ruthenium is formed on the ruthenium. The nitrite layer of the nitrite layer can be used as a hip. Stop: the layer is formed on the p-type well, the dispersion caused by nitriding: can be two, in - preferably, ... (d) deposition of the inter-electrode oxide layer. The final conductive layer is patterned to form the upper plate and the ΗV gate of the valley σσ. The above and other objects and features of this (4) are made clear. The following is a preferred embodiment, and is accompanied by s The details are as follows: [Implementation] The present invention provides a brake t (HV-Gu) technology for manufacturing a semiconductor to a hardened, mixed signal mode body element including a capacitor disposed in the "method," The semi-conducting of the present invention, BH ^ between the voltage gate and a low voltage gate. The invention is based on the invention of the semiconductor component 7 cattle " ^ 兀 above. Ben, Shengshi from Ding Zidan / The township and the boron are diffused to the HV oxidation zone. (Comparatively, the effect of scale diffusion to the η-type well is lower.) The following 2α.^ Example. The lower music 2-8 to the map shows this One of the inventions is a real 0503-A32446TWF/kai 200814312. Figs. 2A to 2F are cross-sectional views of a semiconductor device. The components of the embodiment are similar to those of the first embodiment, and have a capacitor substrate and a HV gate. Similar to the previous case, first two wells are formed on the semiconductor substrate. In this embodiment, the n-type well 115 is formed in the substrate 1〇5 and between the 卩-type well 11〇 and the p-type well 12〇, as shown in the second figure. Then the thin chamber is sequentially formed. The polar oxide layer and the field oxide structure 126 127, 128, 129 ' are as shown in Fig. 2. It should be noted that the relative sizes of the above structures may be moderately changed. The deposition and patterning processes, such as lithography, form the first A polycrystalline =, 'the polycrystalline stone structure 13 〇 and 135 as shown in Fig. = 135. It should be noted that the polycrystalline 7 structure of the a sequence towel is not formed on the p type well (10). Open > polycrystalline germanium oxide layer 13 8, for example, &# above the structure. Then, the growth step is formed in the material of the grazing dan dan quot 贝 贝 贝 贝 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞 舞Oxidation button and at least a positive integer of 7, 2 and 2 are /, A is a negative integer, as shown in Figure 2D. It can be said that the Si3N4 layer 14〇 is between the electric|cry & plate, can be used as A person + for the structure 16Q up and down to prevent β 1 13 4 layer 140 can be used as a boron stop layer, and Slowing down the diffusion of oxygen in the deposited HV gate. In this embodiment, the = p-well 110 is the gate-oxidized material, and the (iv) coffee deposition technique is used to deposit the material to form the inter-polar oxidation structure; 45, = wide ^ ^^ X图图不。 〇5〇3-A32446TWF/kai 10 200814312 On the semiconductor device 100, the polycrystalline layer is patterned to form a second polycrystalline layer, as shown in Fig. 2E. The upper plate i of the upper plate i = yi '160, such as the pole 155 formed on the inter-electrode oxide layer uJT4 layer 140, and the gate 4 (or other ions. As described above, due to the use of boron expansion The layer of the extreme oxide layer (4) is used to prevent or slow down the barrier of the material by the pH. This is also called the boron barrier layer, and the boron diffused out of the earth due to the semiconductor component of the invention. Between the two brothers of the second brother and the third well, the shape of the seven brothers is on the third well, forming the first __ Wei layer in the first, second and second generation conductive structures in the oxidation and #井 and nitriding矽(SisN4) ion barrier sound--, then deposit a layer of Si3N4 formed on the first and second-two, and the third well, the second oxide layer, forming a third conductive structure Forming the first guide Leishe Μ 古 古 古 构 构 构 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井 井a dielectric layer, a final-idle pole, as a high-voltage; an inter-pole:: a: conductive structure can be formed into a Ρ-type well. In the embodiment, the third well is in another embodiment, It is called 乂 可 旦 旦 旦 旦 旦 旦 ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( The number, y and z are any non-negative integers. One X is any positive. The formation method of this embodiment includes a day-to-day oxide film, for example, 503-A32446TWF/kai 11 200814312, as in the deposition of Si3N4 layer (epitaXial) -growth). Form a second oxide layer in the other -fm two program. The third and fourth coffee deposits can be deposited in the same program. , , - structure, such as Xi Jing, in another implementation In one embodiment, the present invention provides a method of forming, comprising providing a substrate, forming a deposit of +¥脰, a nitride layer on a p-type well, a well on a wire plate, (or other ion barrier layer), and p Type well ^ H = nitrite eve:: into this oxide layer, and form a conductive structure in the oxygen ^ closed pole, for example, can be used as - high power plant excitation J = =:: method further includes forming - capacitor adjacent to this gate The layer (4) is formed into a first plate, which is formed on the second plate. The dielectric layer includes oxidation: the second plate is above the dielectric layer. The idler and the second plate may be formed of a phased material and a polycrystalline germanium patterned layer. °, in the - embodiment towel, preferably at the same time the money is cut into the P-type well. The dielectric layer of the layer and the dielectric layer is on the first plate and is in the polycrystalline polycrystalline silicon oxide. ^ And in the pre-cutting wire, although the present invention has been disclosed in the preferred embodiment such as ±, autumn = = Ming, any person skilled in the art, without leaving the inside of the 'when it can make some changes and retouching, therefore this The invention is based on the scope defined in the patent application. 〇503-A32446TWF/kai 12 200814312 [Simple description of the diagram] Figure 1A shows the formation of p-type well and n-type well area on the substrate. The first diagram shows the formation of a field oxide structure, and a HV gate oxide layer is formed on the crucible well region. Fig. 1C shows that the second gate oxide layer is formed on the entire surface of the semiconductor element. Figure 1D shows the formation of a conductive structure. The first block shows that the polycrystalline turn oxide layer/high temperature oxide layer is formed on the conductive structure. Figure 1F shows the deposition of a second conductive layer on the polysilicon inter-turn oxide/high temperature oxide layer to form the upper conductive layer of the capacitor. The second figure shows the formation of a p-type well and an n-type well region on a semiconductor substrate. The second figure shows the formation of a thin gate oxide layer and a field oxide structure in sequence. Figure 2C shows that the polysilicon structure is formed on the gate oxide layer. Figure 2D shows the deposition of a layer of tantalum nitride material after formation of a field oxide structure. The second figure shows the formation of a gate oxide structure. Figure 2F shows the semiconductor structure of the present invention. [Major component symbol description] 10~Semiconductor component; 12~substrate; 15, 25~Ρ type well; 20~Ν type well; 30, 31, 32, 33~ field oxidation structure; 35~HV gate oxide layer; ~ second gate oxide layer; 45, 46, 47~ conductive structure; 50~ polysilicon turn oxide layer/high temperature oxide layer; 0503-A32446TWF/kai 13 200814312 55~ second conductive layer; 105~ substrate; 115~n type Well; 126, 127, 128, 129 130, 135~ polycrystalline structure 13 8 ~ polycrystalline oxide layer; 145 ~ gate oxide structure; 155 ~ gate; 100 ~ semiconductor element; 110,] 20 ~ ρ Well, · 125~ thin gate oxide layer, field oxide structure; j 140~ tantalum nitride (Si3N4) layer; 15 0~ upper plate; 160~ capacitor structure. 0503-A32446TWF/kai 14

Claims (1)

200814312 X. Patent Application Range··1· A semiconductor device comprising: a capacitor; comprising: a first conductive layer; a second conductive layer disposed above the first conductive layer; a boron barrier layer disposed on the Between the first and second conductive layers as a dielectric layer; and a high voltage gate adjacent to the capacitor; comprising: a boron barrier layer; and a conductive layer disposed on the boron barrier layer. 2. The semiconductor device according to claim 2, wherein the boron barrier layer comprises tantalum nitride (Si3N4). 8. The semiconductor component according to claim 1, wherein the boron barrier layer comprises a nitrogen oxide button (TaxOyNz), a nitrogen oxidization error (Zr〇yNz), a zinc oxynitride (Zn〇yNz), Carbonization dream (8) ❽ and at least one material of 氮 氮 (1 (SlX〇yNz), where X is any positive integer, y and IZ are any non-negative integers. ^ and ^ 4 · as claimed in item 1 The semiconductor device, wherein the high voltage gate further comprises a first oxide layer and a second oxide layer, and the two are separated by the boron barrier layer. The semiconductor component according to claim 丨The boron barrier layer of the germanium valley state and the boron barrier layer of the high voltage gate are deposited by a process. 6. The semiconductor component according to claim 5, wherein 0503-A32446TWF/ Kai 200814312 The boron barrier layer is a film. 8. The semi-integrated low voltage (LV) gate as described in claim 1 of the patent application. 9. The half of the low-voltage gate as described in claim 8 The pole includes a boron barrier layer. 7. The boron resistance as described in claim 6 The thickness of the layer is between 100 and 5 in., /, the middle conductor element, and the other is the conductor element, wherein "半导体. The semiconductor device according to the scope of claim [i] is formed in the voltage gate. ) type well. The semiconductor component according to claim 4, wherein the capacitor is formed on an n-type well and the high voltage gate is shaped on the well. P12. The semiconductor component of claim 1, wherein a low voltage gate is formed on a p-type well. 13. The semiconductor component according to claim 12, wherein The n-type well is disposed between the p-type well of the low voltage gate and the p-type well of the high voltage gate. A semiconductor device comprising: a substrate comprising a p-type well; and a high voltage gate structure formed on the P-type well, wherein the high-voltage gate-extreme structure comprises a layer formed on a boron barrier layer Gate. The semiconductor device according to claim 14, wherein the boron barrier layer comprises tantalum nitride (Si3N4). 16. The semiconductor component according to claim 14, wherein 0503-A32446TWF/kai 16 200814312 = barrier layer comprises nitrogen oxide (TaA, Nz), oxynitride = he), zinc oxynitride (Zn 〇) At least one material of yNz), carbonized state, and nitrogen oxynitride 〇h〇yNz), wherein χ is any positive integer, and ζ is any non-negative integer. ^二——The semiconductor component described in claim 14 of the patent application, further comprising an oxide layer. Well isolation. 18. The semiconductor device as claimed in claim 4, wherein the capacitor comprises a lower plate, an upper plate and an electrical layer interposed between the upper plate and the lower plate. A semiconductor device, comprising: a capacitor, comprising: a first conductive layer; and a second conductive layer between the conductive layers, disposed on the first conductive layer, a layer of tantalum nitride (SisN4), Provided on the first and the first as a dielectric layer; and a high voltage gate adjacent to the capacitor, comprising: a first oxide layer; a tantalum nitride (Si3N4) layer; a second oxide layer; The tantalum nitride (Si3N4) includes: a conductive layer disposed on the first oxide layer and the second oxide layer. The method for manufacturing a semiconductor device provides a substrate; the method includes: forming a capacitor on the substrate 0503-A32446TWF/kai 17 200814312 to form a first conductive layer; forming a boron barrier layer on the first conductive layer And a second conductive layer on the boron barrier layer, wherein the boron barrier p is an early layer as a dielectric layer; and a negative voltage is formed in a vicinity of the capacitor, wherein the height is: A boron barrier layer is included, and a conductive layer is over the boron barrier layer. 21. The method of fabricating a semiconductor device according to claim 2, wherein the boron barrier layer comprises tantalum nitride (#4). The bismuth barrier layer of the semiconductor device described in claim 20 includes the oxynitride group (τ_, nitrous oxide sulphate (six〇yNZ, rat milk, chemistry (Zn〇yNz) ), carbon carbide (SixCy) and nitrogen oxides y and z are any non-negative integers. Jade number 23. As described in the scope of the patent application, the semiconductor device is described in the above, wherein the high voltage gate further includes - a first oxide layer and a - aramid, and the two are isolated by the boron barrier layer. 24. The second component of the semiconductor component described in the scope of claim 5 is made up of a barrier layer of the device and The high voltage gate is formed by a process as described in the second aspect of the invention. The method includes wherein the boron barrier layer is a film. 26. The patented semiconductor component (4) method of claim 2, wherein the boron barrier layer has a thickness between 100 and 500 A. 〇503-A32446TWF/kai 18 200814312 includes forming a low voltage ( LV) gate is in the manufacturing side = application for the special touch of the 27th item of the ^ " medium ° low electrical gate includes a boron barrier layer. The method for manufacturing a semiconductor device according to claim 20, wherein the high voltage gate is formed on a P-type well. 30. The semiconductor according to claim 2 () The manufacturing method of the device, wherein the capacitor is formed on the “n-type well”, and the thick gate is formed on a P-type well. The method for manufacturing the semiconductor device according to the third aspect of the patent application includes a The low voltage gate is formed on a p-type well. The method of manufacturing the semiconductor device according to claim n, wherein the n-type well is disposed in the p-type well of the low voltage gate and the high voltage Between the p-type wells of the gate. 0503-A32446TWF/kai 19